Classifications

• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
  • G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
  • G01R31/36—Arrangements for testing, measuring or monitoring the electrical condition of accumulators or electric batteries, e.g. capacity or state of charge [SoC]
  • G01R31/382—Arrangements for monitoring battery or accumulator variables, e.g. SoC
  • G01R31/3835—Arrangements for monitoring battery or accumulator variables, e.g. SoC involving only voltage measurements
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
  • G01R19/00—Arrangements for measuring currents or voltages or for indicating presence or sign thereof
  • G01R19/165—Indicating that current or voltage is either above or below a predetermined value or within or outside a predetermined range of values
  • G01R19/16533—Indicating that current or voltage is either above or below a predetermined value or within or outside a predetermined range of values characterised by the application
  • G01R19/16538—Indicating that current or voltage is either above or below a predetermined value or within or outside a predetermined range of values characterised by the application in AC or DC supplies
  • G01R19/16542—Indicating that current or voltage is either above or below a predetermined value or within or outside a predetermined range of values characterised by the application in AC or DC supplies for batteries
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
  • G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
  • G01R31/36—Arrangements for testing, measuring or monitoring the electrical condition of accumulators or electric batteries, e.g. capacity or state of charge [SoC]
  • G01R31/382—Arrangements for monitoring battery or accumulator variables, e.g. SoC
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
  • G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
  • G01R31/36—Arrangements for testing, measuring or monitoring the electrical condition of accumulators or electric batteries, e.g. capacity or state of charge [SoC]
  • G01R31/392—Determining battery ageing or deterioration, e.g. state of health
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
  • G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
  • G01R31/36—Arrangements for testing, measuring or monitoring the electrical condition of accumulators or electric batteries, e.g. capacity or state of charge [SoC]
  • G01R31/396—Acquisition or processing of data for testing or for monitoring individual cells or groups of cells within a battery
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
  • H01M10/00—Secondary cells; Manufacture thereof
  • H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
  • H01M10/44—Methods for charging or discharging
  • H01M10/441—Methods for charging or discharging for several batteries or cells simultaneously or sequentially
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
  • H01M10/00—Secondary cells; Manufacture thereof
  • H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
  • H01M10/44—Methods for charging or discharging
  • H01M10/443—Methods for charging or discharging in response to temperature
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
  • H01M10/00—Secondary cells; Manufacture thereof
  • H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
  • H01M10/44—Methods for charging or discharging
  • H01M10/446—Initial charging measures
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
  • H01M4/00—Electrodes
  • H01M4/02—Electrodes composed of, or comprising, active material
  • H01M4/04—Processes of manufacture in general
  • H01M4/0438—Processes of manufacture in general by electrochemical processing
  • H01M4/044—Activating, forming or electrochemical attack of the supporting material
  • H01M4/0445—Forming after manufacture of the electrode, e.g. first charge, cycling
  • H01M4/0447—Forming after manufacture of the electrode, e.g. first charge, cycling of complete cells or cells stacks
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
  • H01M10/00—Secondary cells; Manufacture thereof
  • H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
  • H01M10/44—Methods for charging or discharging
  • H01M10/448—End of discharge regulating measures
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
  • Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
  • Y02E60/10—Energy storage using batteries

Definitions

• the present invention relates to methods for determining a reference energy profile, to a device for forming a battery, to a method for forming a battery, to a use of a reference energy profile, and to a computer program.
• the present invention further relates to a method for the improved formation of galvanic cells or electric battery cells forming a solid electrolyte interface (SEI) and to an optimized method for shaping current guidance.
• SEI solid electrolyte interface
• a manufacturing step in the production of galvanic cells or electric battery cells is the formation.
• Forming is the name given to the first charge and discharge processes in which the so-called SEI (Solid Electrode Interface SEI, solid electrolyte interface) is formed.
• SEI Solid Electrode Interface SEI, solid electrolyte interface
• This process is necessary to activate the electrochemical processes and / or properties of the battery cell.
• the formation of the SEI plays a crucial role for important cell properties, such as internal resistance and cycle stability.
• An advantage is a stable, even layer. In the process, it has hitherto been formed with very low electrical currents (that is to say charged and discharged). This in turn leads to a time-consuming and therefore cost-intensive production step, which can restrict the throughput of the production chain.
• FIG. 11 shows a schematic representation of a concept 90 for forming a battery cell 92 according to the prior art.
• the battery cell 92 is electrically connected to a DC power source 96 via contacts 94a and 94b.
• the formation is carried out with a constant current I.
• the current I can also be controlled by means of a controller 98 so that it is increased in a few, predefined stages, wherein a constant current value is set between the stages.
• DE 3736069 A1 describes the use of a regulated current for the formation of lead-acid batteries.
• a different electrochemical target is pursued here.
• the structure of an SEI comprises forming an electrically insulating layer between active particles (electrode) and the electrolyte.
• the electrochemical processes are not comparable. It would therefore be desirable to have a concept for forming a battery which makes it possible to carry out improved formation of batteries with little expenditure of time compared to known methods and / or to obtain an SEI with a high degree of homogeneity. It is an object of the present invention to provide a concept which enables a battery to be formed with a low expenditure of time and / or a high SEI homogeneity.
• the gist of the present invention is to have realized that the above object can be achieved by dynamically applying an amount of energy supplied to a battery during a forming operation based on a consideration of an actual SEI formation over a time course of the forming process. time can be determined. The amount of energy so determined allows a high over the time course adaptation of Formierstromposition to the SEI formation and / or adjustment of the amount of energy so that the formation of the SEI is homogeneous.
• a finding of the present invention is that the SEI formation can be uneven during the supply of an energy quantity to the battery to be formed. The unevenness can lead to variable SEI education rates and / or uneven layer homogeneity.
• An adaptation of the amount of energy to the actual state of the battery to be formed allows for at least a temporary acceleration of the formation process and / or an at least temporary formation of the SEI with a high homogeneity, so that overall a SEI with a high layer homogeneity can be obtained quickly.
• An amount of energy to be supplied during formation may be determined based on a comparison of an energy consumption between a first charge cycle and a second charge cycle of the battery.
• a deviation between the first and the second course of an energy intake in a time interval makes it possible to draw conclusions about a circumference in the SEI during which time interval is formed, so that a dynamic adaptation of the amount of energy to be supplied to the battery can take place.
• a method for determining a reference energy profile comprises comparing a first profile, which describes a power consumption of a first battery during a first charging cycle, with a second profile, which shows the energy consumption of the first or a second battery during a second charging cycle first charge cycle follows describes.
• the comparison is performed for a plurality of time intervals.
• the method further comprises determining a deviation between the first and second traces for each of the plurality of Time intervals.
• the method further comprises determining an amount of electrical energy based on the deviation for each of the time intervals, wherein the electrical energy describes a target value of the reference energy profile for an amount of energy to be supplied to a battery to be formed during a forming process of the battery to be formed for each of the time intervals.
• a reference energy profile can be obtained for the same or similar batteries that allows for a high level of SEI formation in at least one, several, or all of the time intervals, such that a period of time until formation is complete. short and thus a time efficiency of the formation can be high.
• a uniform SEI formation can be obtained, so that the SEI is obtained with a high quality.
• a method of determining a reference energy profile comprises comparing a first history describing an energy intake of a first battery during a first charging cycle with a second history representing the energy consumption of the first or second battery during a second charging cycle based on the first energy first charge cycle follows describes.
• the comparison is performed for a plurality of time intervals.
• the method further includes determining a deviation between the first and second traces for each of the plurality of time intervals.
• the method further comprises determining that an amount of electrical energy supplied to another battery during formation thereof is reduced in a subsequent time interval based on the comparison when the comparison indicates that an amount of formation other than the electrical Energy is less than or equal to 80% of a formable by the electrical energy forming.
• the course of the electrical energy over the plurality of time intervals describes the reference energy profile at least partially.
• a deviation between the courses may indicate that a proportion of more than 20% of the electrical energy is spent in charging the battery and thus not for the formation of the SEI.
• the proportion can be reduced to form a fast and / or high quality SEI.
• a reference energy profile according to previous embodiments is used to apply the electrical energy according to the reference energy profile to the battery to be formed.
• a device for forming a battery comprises a controllable energy source, which is designed to supply an electrical energy to a battery coupled to the controllable energy source.
• the apparatus includes a controller configured to control the controllable energy source at a plurality of time intervals.
• the device further comprises a detection device, which is designed to determine a physical state of the battery in each of the time intervals.
• the controller is configured to control the electrical energy source based on the detected physical condition so as to increase or decrease an amount of electrical energy supplied to the battery during a subsequent time interval.
• FIG. 1 shows a schematic flowchart of a method for determining a reference energy profile according to an embodiment
• FIG. 2 shows a schematic flowchart of a further method for determining a reference energy profile according to an exemplary embodiment
• FIG. 3 is a schematic flowchart of a method for determining a
• FIG. 4 shows a schematic diagram in which a section of a first course and a section of a second course of a charging cycle are illustrated according to an exemplary embodiment
• FIG. 5 is a schematic flowchart of a method of forming a battery according to an embodiment
• FIG. 6 is a schematic block diagram of an apparatus for using a reference energy profile according to an embodiment
• FIG. 7 is a schematic block diagram of an apparatus for forming the battery according to an embodiment
• FIG. 8 is a schematic block diagram of a device having a memory opposite the device of FIG. 7 configured to store a reference energy profile, according to one embodiment
• FIG. 9 is a schematic diagram showing a profile of a battery voltage during a forming process, as may be obtained in accordance with an aspect of embodiments described herein;
• FIG. 10 is a schematic flowchart of a method for forming a battery according to an embodiment
• Fig. 11 is a schematic illustration of a concept for forming a battery cell according to the prior art
• 12a-b are schematic representations of methods for forming a battery by using a reference energy profile according to embodiments described herein;
• 12c-d are schematic illustrations of methods of forming a battery by adjusting a standard profile according to embodiments described herein.
• Embodiments described below relate in part to the determination of an electrical energy supplied for the purposes of forming a battery. Although exemplary embodiments relate to determining a profile of characteristics or physical states of the battery and / or determining a quantity of electrical energy for a charging process of the battery, subsequent explanations without relevant restrictions are also applicable to a discharging process of the battery.
• a predetermined current can be applied to the battery. A positive current may result in a charge on the battery, while a negative current may result in a discharge of the battery and / or a negative charge on the battery, with SEI formation occurring during charging and discharging.
• the process described below as loading may describe charging or discharging of the battery, the procedure described below as discharging being described only as the complementary operation, ie. h., Should be understood as a discharge or as a charge.
• a subsequent amount of energy supplied to a battery may also be negative based on, for example, a negative current. This can lead to charge carriers being removed from the battery when the amount of energy is supplied.
• subsequent embodiments relate in part to the determination and / or use of a reference current profile that includes information regarding a current to be provided by a controllable power source
• a reference energy profile that provides information regarding one having the battery to be formed to be provided electrical energy. This may be, for example, a quantity of charge to be provided and / or an electrical voltage which is provided by a controllable energy source. If, for example, a (shunt) resistance of the device is known, this can be converted into the current to be formed to the battery to be formed.
• the reference energy profile can thus provide information about the have exhibiting electrical energy.
• the electrical energy may relate to an electrical current, to an electrical voltage, to an electrical charge and / or to a quantity of electrical charge carriers.
• the method comprises a step 110, in which a first course is compared with a second course.
• the first profile describes an energy intake (for example a charge carrier increase, charge carrier decrease and / or a value derived therefrom) of a first battery during a first charge cycle.
• the second course describes an energy intake of the same or another battery during a second charge cycle.
• the second charge cycle follows the first charge cycle.
• the first charge cycle may be the actual first (initial) charge cycle during which the formation of the battery is at least partially performed.
• the second charge cycle may be a subsequent charge cycle during which the battery is recharged.
• the second charge cycle may be the actual second charge cycle following the first discharge cycle, or alternatively another charge cycle (eg, third, fourth, fifth or further) comparable to the first charge cycle.
• a use of the second charging cycle since the comparison between the charging cycles is only spaced by a discharge cycle.
• the comparison is carried out for a multiplicity of time intervals.
• the multiplicity of time intervals may relate to a period of time during which the formation takes place, ie the formation of the SEI in the battery.
• the second course of an at least partially or completely formed battery and the first course of an at least to a lesser extent or not formed battery can be assigned.
• the time intervals may be a time (span) that elapses during a period of the charging cycle.
• the time interval may be a time period during which the first or second battery has a specific or unchanged physical state within a tolerance range.
• the physical state can be, for example, a voltage that is present between poles of the battery (can be tapped off).
• the physical state may be a current that is received by or released from the battery.
• the physical state may be a temperature to which the battery is brought during the forming process or a temperature which the battery itself has.
• the physical state is one or more quantities derived therefrom.
• this may be a change in voltage between poles of the battery, which is set in relation to a received charge amount.
• time interval can also be understood to mean, for example, a time duration or a point in time during which the battery has the respective physical state unchanged or within a tolerance range unchanged.
• the tolerance range may, for example, be within a deviation of at most 20%, at most 10% or at most 5% of the value of the first or second course.
• the method 100 includes a step 120 in which a deviation between the first and second traces is determined for each of the plurality of time intervals. The deviation may be based on a mathematical operation such as difference, quotient formation or the like. For example, a difference between the energy consumption of the first course in a time interval and an energy intake of the second course can take place during the same or a comparable time interval.
• the energy consumption can refer to a voltage change dU, which is obtained as a function of a recorded amount of charge dQ at the battery poles.
• the course can be represented, for example, via a monotonically increasing battery voltage, as will be explained later in connection with FIG. 4.
• the method 130 further includes determining an amount of electrical energy based on the deviation for each of the time intervals.
• the electrical energy describes a target specification of the reference current profile for an amount of energy that is to be supplied to a battery to be formed during a forming process of the battery to be formed for each of the time intervals.
• the deviation may refer to an occurring voltage change per charge amount between the courses.
• a large deviation may provide information that during the time interval in which the deviation between For example, if a trace associated with an at least partially formed battery and associated with a trace of a smaller-sized battery occurs, a high level of the energy provided for the formation of the SEI will be realized.
• a small deviation may provide information that the amount of energy supplied (or carrier) leads to a low formation of SEI.
• the reference current profile may include, for a time interval for which information about a high level of formed SEI is present, an indication that an amount of energy to be supplied to the battery to be formed should be low (eg in the form of a low current), so that during this time interval a homogeneous SEI formation can be obtained with a high quality.
• the reference current profile may include an instruction that a high current is to be supplied to the battery to be formed. This can lead to this time interval being able to be passed through quickly.
• the deviation can be interpreted as meaning that a physical state of the battery in which little SEI is formed is traversed quickly, while a physical state in which a high level of SEI is formed is passed slowly through.
• an advantage of this embodiment is that the reference current profile thus obtained can be taken into account the current state of the battery to be formed and that for each time interval, an amount of energy to be supplied is redeterminable.
• the amount of energy can be increased or decreased between time intervals.
• the amount of energy may, for example, relate to a current to be supplied to the battery to be formed.
• it can be, for example, an electrical voltage that is output by a power source and is optionally passed through an electrical resistance as an electrical current to the battery.
• the determination of the amount of electrical energy may be based on a conversion function.
• the conversion function can have at least one function argument, which is mapped to a function value.
• the function argument may be, for example, the particular deviation.
• the function value may be the electrical energy or a value correlated therewith.
• the correlated value may be any value based on which a controllable energy source may be controlled to provide a corresponding amount of electrical energy, for example, a value of dex, a relative magnitude of a current or voltage or an absolute value thereof.
• the function value of the conversion function may describe an electric current or an electric charge. An exemplary conversion function will be explained with reference to FIG. 4 described below.
• the first battery may be, for example, a reference battery or a battery from a production batch.
• the first course can be done by charging (first charging cycle) of the first battery. Subsequently, the first battery can be at least partially discharged and then reloaded (second charge cycle) to obtain the second course.
• at least one further charging cycle and / or at least one further discharging cycle may be arranged between the first charging cycle and the second charging cycle.
• the second course can be determined based on a charging process of a second battery.
• the second battery may, for example, have at least the same or a comparable property as the first battery.
• the characteristic may, for example, include a shape (such as the battery cell, the electrodes, a volume in which electrolyte is disposed), at least one electrical characteristic (cell size, charging voltage, geometry, or the like).
• the second battery may, for example, be a battery of identical construction, which may be manufactured in the same production batch as the first battery.
• the first course and / or the second course each describe an average value over a multiplicity (2, 3, 4 or more) of batteries, for each of which the corresponding course is determined.
• the mean value can be a geometric, a quadratic or even a median mean. Averaging allows a high degree of match of the profile of the reference current profile across a plurality of batteries.
• the profiles can also be created based on a model and / or a computer simulation, for example by modeling (modeling or simulating) the formation of the SEI based on the applied current intensity.
• the first course, the second course and / or the reference current profile can be a continuous course, for example in the form of a superimposition of functions.
• the first profile, the second profile and / or the reference current profile may be a plurality of discrete values which enable interpolation or extrapolation of further values.
• FIG. 2 shows a schematic flowchart of a method for determining a reference current profile according to an exemplary embodiment.
• the method 200 comprises a step 210.
• a first course which describes an energy intake of a first battery during a first charging cycle
• the second course describes the energy intake of the first or a second battery during a second charging cycle following the first charging cycle.
• the comparison can be performed for a variety of time intervals.
• Step 210 may be step 110.
• a deviation between the first and the second course is determined for each of the plurality of time intervals, as described for the step 120.
• a determination is made that an amount of electrical energy which is supplied to a further battery to be formed during formation of the same is reduced in a subsequent time interval. This can be done based on the comparison. For example, the comparison may indicate that an amount of formation caused by the supplied electrical energy is greater than or equal to 40%, greater than or equal to 60%, or greater than or equal to 80% of an electric energy-impartable formation.
• a proportion can be deduced by, for example, making measurements on reference batteries (possibly at different time intervals) or by performing simulations for a corresponding type of battery.
• a deviation value can be correlated with the share by means of a conversion function.
• a course of the electrical energy quantity determined over the plurality of time intervals may at least partially describe the reference current profile.
• the reference current profile can be obtained by considering the particular amount of electrical energy over the plurality of time intervals.
• the method 200 makes it possible to increase the amount of energy supplied as needed, for example if a low level of SEI is being formed and to speed up the method.
• the method also allows for a reduction of the energy amount if necessary. This requirement may, for example, occur when a high level of electrical energy, ie at least 40%, at least 60% or at least 80% of the electrical energy supplied is converted into the formation of the SEI.
• the SEI can be formed to a greater extent, the formation of the SEI has taken place in a more homogeneous state and / or the forming process (charging cycle) has taken place in a shorter time.
• the first and second charging cycles may be based on a current applied to the battery having a constant or predefined (possibly variable) value.
• the constant current can have any value, for example 1/50 C, 1/30 C, 1/10 C or a value in between.
• the value 1 C describes a specified example in mA current of the battery. For example, if the battery has a capacity of 2000 mAh, 1 C may correspond to a current of 2000 mA.
• the method 100 and / or 200 may be performed such that a first or second course is associated with a particular load or unload operation. Furthermore, the method 100 and / or 200 may be executed repeatedly. For example. For example, a repetition can be carried out in such a way that in a first repetition (second embodiment) the first course substantially or completely corresponds to the second course of a preceding embodiment.
• a formation may comprise 2, 3, 4, or 5 charge and / or discharge cycles.
• a reference current profile can be created and / or used for repeated charging and discharging cycles of the battery.
• a method of forming a battery may be repeatedly performed in at least one repetition.
• the first course and the second course of a respective embodiment may be associated with a charging or discharging cycle of the battery to be formed.
• the first course or the second course of a repetition with respect to the first course may be changed compared to the first or second course of a preceding embodiment of the method.
• the charge or discharge of a battery may be repeated until the battery is sufficiently formed, such as a number of 2, 3, 4, 5, or more charge cycles.
• FIG. 3 shows a schematic flowchart of a method 300 according to one exemplary embodiment.
• the method 300 may be used to, for example, the Compare the first and second course, as it is done for the steps 1 10 and 210 to execute.
• the method 300 includes a step 310.
• a charge amount that is taken up by the first or second battery is determined.
• the charge amount is determined for each of the plurality of time intervals.
• the method 300 comprises a step 320.
• a ratio between the recorded charge amount and a voltage change which describes a change in an electrical voltage applied to battery poles of the first and second battery is formed. The ratio is formed for each of the plurality of time intervals.
• FIG. 4 shows a schematic diagram in which a section of a first course (forming cycle) 12 and a section of a second course (forming cycle) 14 are illustrated.
• the courses 12 and 14 describe, for example, in each case one charging cycle, the explanations readily applying to one discharging cycle.
• a monotonically increasing voltage in volts is plotted.
• the electrical voltage can be a physical electrical voltage which is present or can be tapped between a positive pole and a negative pole of a battery. Alternatively or additionally, the electrical voltage may be a simulation result of the physical electrical voltage (that is, for example, a mathematical value).
• a voltage gradient dU / dQ is plotted on the ordinate of the diagram, which describes the change dU in the voltage plotted on the abscissa in relation to a charge quantity dQ obtained from the respective battery.
• the voltage gradient may be determined based on a particular amount of charge received by the first or second battery for each of the plurality of time intervals.
• the ordinate has the unit V / mAh.
• the diagram can be obtained, for example, by applying an electric current with an optionally low amperage to the battery. This can lead to an increase in the stress (abscissa), with the gradient (change or rate of change) being shown on the ordinate.
• the value specifications of the abscissa and the ordinate are merely exemplary and schematic and are not intended to exert any limiting effect.
• the curves 12 and 14 are shown in an exemplary operating range of a battery.
• the working range illustratively has a lower limit of about 3 volts and an upper limit of about 4.2 volts.
• Other gradients may have different lower and / or upper limits.
• Other waveforms may be determined in at least one range including another lower limit (approximately in about 0 volts, 1 volt, or other value) and / or another upper limit (about 2 volts, 3 volts, 5 volts, or other value).
• At least one of the courses 12 or 14 may also be determined in sections, for example in a section which is outside the working area (for example based on a simulation or reference measurement on a deep-discharged battery) and in a section within the working area (for example by measurement during the charging process ).
• the diagram has, for example, four deviations 16a-d in between the first course 12 and the second course 14 in four time intervals 18a-d.
• the traces 12 and / or 14 may be subdivided into a plurality of time intervals.
• the time intervals taken together may comprise or comprise at least 20%, at least 50%, or at least 80% of the charge or discharge cycles.
• only four time intervals 18a-d are shown, wherein the plurality of time intervals (for example more than 2, more than 5 or more than 10) can be joined together seamlessly over the courses, if necessary.
• the first deviation 16a is at a voltage of about 3.1 V, a second deviation 16b at a voltage of about 3.17 V, a third deviation 16c at a voltage of about 3.3 V, and a fourth deviation 16d at a voltage of approximately 4.15V.
• a charge-specific voltage increase of the first charging cycle is relatively low.
• the diagram evidently has a high dU / dQ value, the voltage in this area can increase more strongly due to the battery chemistry, ie the normal voltage increase is greater here.
• the reference that is, the following progression
• the battery having a further developed state can thus be taken as normal and compared with the current or previous cycle to estimate the SEI formation (which makes the two curves vary). This means that there is a large difference (deviation) 16a. This allows us to conclude that a strong SEI formation is taking place. This, in turn, allows determining the amount of electrical energy for a reference current profile (such as in step 130) with a small amount of current.
• the deviation values of the deviations 16a-c decrease, for example, starting from the deviation 16a via the deviation 16b to the deviation 16c. This means that it can be concluded on a sinking SEI education. This in turn allows the determination of the amount of electrical energy such that the reference current profile has information that in the time intervals 18a-c an increasingly large amount of energy is to be supplied to the battery to be formed.
• a deviation may also be small.
• the determination of the amount of electrical energy in this case can be carried out so that the reference current profile has information that a high or maximum current in the time intervals to be supplied to the battery.
• a length of the time intervals 18a-d can be made arbitrarily small.
• a time length of a time interval of the reference current profile may describe a time period in which the first curve 12 or the second curve 14 carries out a change of at most 0.01 V, at most 0.05 V or at most 0.21 V.
• the duration of a time interval 18a-d may also relate to or correlate to a time period within which the battery has an electrical voltage which is within a tolerance range of at least 0.01% and at most 30%, of at least 0, 05% and at most 10% or at least 0.09% and at most 1%, for example, with about 0, 1% is unchanged.
• a length of the time intervals 18a-d may also be obtained based on a time duration, such as in a range between 10 seconds and 3 hours, in a range between 1 minute and 1 hour, or in a range between 5 minutes and 30 minutes.
• the dU / dQ value of the first curve 12 drops, for example, again in comparison to the second charging process.
• the reference current profile may include an instruction to provide a reduced current.
• a difference (deviation) as a function of the voltage can be calculated from the two curves 12 and 14.
• a quotient comprising a value of the first curve 12 and a value of the second curve 14 may also be used to determine the deviation.
• the deviation can be referred to as D i (U) , for example.
• the conversion function f can be set, for example, such that the current intensity at the beginning (actual type) has a value between 1/50 C and 1/5 C, 1/30 C and 1/10 C, approximately 1/20 C (ie NEN between l / 50 and ⁇ ⁇ / 10).
• This current intensity may, for example, increase linearly, exponentially, or with another relationship to coincidence with a predetermined maximum value, approximately 1 C (1 N ).
• the diagram or the complete reference method may be displayed and / or values even over a time axis (l i (t)) or absolute charge (l i (Q)) or electrical energy axis (l i (E)) which are calculated accordingly.
• a variable conversion function can also be used.
• a first voltage range of the battery for example, outside the working range
• a first conversion function or a constant current with a constant value can be applied to the battery.
• a second voltage range such as within the operating range of the battery
• another conversion function may affect a particular value of the current.
• the conversion function can be variable over a load or unload operation.
• a voltage obtained at poles of the battery which may change during a charge or discharge cycle, a voltage change (possibly in response to a charge transferred to the battery), and / or an amount of charge applied to the battery may have a mutual relationship to each other and least with a sufficient accuracy be feasible.
• Other profiles, deviations and / or reference energy profiles can thus relate to a voltage, a voltage change and / or a charge quantity.
• an electrical energy amount can be determined for each of the time intervals.
• the amount of electrical energy may describe a target value of the reference current profile for an amount of energy to be supplied during a forming process of a battery to be formed.
• the determination of the amount of electrical energy can be based on a conversion function with at least one function argument (deviation).
• the determination of the deviation may also include a quotient formation of a value of the first curve 12 and the second curve 14.
• the reference current profile can, for example, specify a constant current intensity for a time interval.
• the time interval may be made so short that a substantially analogous and dynamic change in the current level is achieved.
• the first curve 12 and the second curve 14 are shown as curves, the first curve 12 and / or the second curve 14 may be a plurality of values between which the respective curve is interpolated or extrapolated.
• the reference current profile can be represented as a course, possibly representable as a function, or a multiplicity of values.
• the dU / dQ diagram illustrates how much the voltage has changed in a short time interval dt in relation to the charge introduced or removed.
• dt short time interval
• the first forming cycle (course 12) is compared with the subsequent second cycle (course 14)
• This additional charge is at least partially lost in side reactions, especially SEI formation.
• the difference (deviation) of both curves gives at least partially the magnitude of the SEI formation.
• an optimum shaping current profile as described above can be created. It can be a reference formulation with a low constant electricity.
• the difference between the dU / dQ curves of two, possibly consecutive loading and / or unloading operations can be converted into a power profile using a formula (conversion function).
• 5 shows a schematic flowchart of a method 500 for forming a battery according to one exemplary embodiment.
• a reference current profile according to method 100 or according to method 200 is obtained.
• the obtaining can be done, for example, by storing the obtained reference current profile and / or transmitting it.
• a step 520 of the method 500 the battery is charged with an amount of energy.
• a time course of the energy quantity is based on the reference current profile.
• a controllable energy source may be controlled to deliver an amount of energy to or from the battery based on or in accordance with the reference current profile.
• the reference current profile 22 is created, for example, by the method 100 or 200.
• a controllable energy source 28 coupled to a battery 24 at pads 26a and 26b is configured to supply the electrical energy to the battery 24 in accordance with the reference current profile.
• the reference current profile 22 may be stored in a memory of a control device 32.
• a plurality of reference current profiles may also be stored in the memory 22 to allow repeated execution of the formation with a respectively adapted reference current profile.
• the reference current profile is shown with a profile of a current I over time t.
• the time t may also be understood as a number of intervals or be described in the reference current profile during which the battery 24 has a certain or within a tolerance unchanged physical state, such as a voltage between the battery terminals or pads 26 a and 26b, as described in connection with FIG. 4.
• the controllable energy source may be, for example, a controllable current source or a controllable voltage source. In particular, it may be a controllable DC source.
• the reference current profile can be created, for example, as a function of a current intensity, a voltage level or the amount of charge or energy already supplied.
• the device 70 includes the controllable power source 28 and a controller 34.
• the controller 34 is configured to control the controllable power source 28 at the plurality of time intervals.
• the controller 34 may be configured to control the controllable power source 28 so that a current, a frequency of one or more current pulses, or the like is dynamically changed.
• the device 70 comprises a detection device 36, which is designed to determine a physical state of the battery 24 in at least one, several or each of the time intervals.
• the controller 34 is configured to control the electrical energy source 28 based on the sensed physical condition so that an amount of electrical energy delivered to the battery 24 during the remainder of the current or subsequent time interval is increased or decreased.
• the physical state may be, for example, an electric voltage applied to battery terminals of the battery to an electric current supplied to the battery 24, an amount of electric charge received by the battery, a period of time in which electric energy is received by the battery, to a temperature which is applied to or in the battery and / or related to derived values.
• the physical state may refer to the voltage gradients described in connection with FIG. 4.
• the physical state may also relate to a voltage change of the voltage applied to battery poles of the battery in relation to a charge amount absorbed by the battery (dU / dQ).
• values of a reference current profile may be determined at least in part during the formation of the battery 24 based on the detected physical state and / or based on a sensed history.
• the control device 34 may control the controllable energy source 28 such that a measure of the electrical energy provided remains unchanged, increased or decreased. is lowered. For example, based on a specific heating of the battery 24, an amount of charge can be reduced in order to avoid overheating.
• control device 34 may be configured to associate a physical state measurement value, for example a value provided or derived from the detection device 36, with an energy quantity.
• the controller 34 may further be configured to control the controllable energy source 28 so that the controllable energy source can control the particular amount of energy of the battery within a subsequent time interval, i. a period of time following the determination.
• the time intervals can be so short (for example in about 1 minute) that the adaptation of the electrical energy quantity substantially corresponds to a dynamic DC method.
• the energy quantity can be assigned to a specific temperature of the battery 24, to a specific voltage of the battery 24 or to a specific deviation between courses.
• the controller 34 may be configured to apply a conversion function to the physical state (function argument) to obtain the energy quantity (function value).
• the calculation of the dU / dQ value may also take place directly when the affected cell is formed, rather than predetermining the current profile. This can be compared with the second cycle, such as the curve 14, from the Referenzformmaschine and the difference in the new Formierstrom be converted. This allows for increased consideration for the actual condition of the cell.
• a dU / dQ reference can also be created by means of a model and / or a simulation.
• FIG. 8 shows a schematic block diagram of a device 80 which also has, relative to the device 70, a memory 38 which is designed to store a reference current profile and / or a nominal value specification of a profile (such as curve 12 or 14) or a physical state ,
• the reference current profile may have setpoint specifications for the electrical energy to be supplied to the battery and / or the physical state for at least one of the plurality of time intervals of the charging cycle.
• a control device 34 ' is designed, for example, to control the controllable energy source 28 based on the reference current profile stored in the memory 38.
• the control device 34 is designed, for example, to detect a deviation between the physical state for at least one, several or each of the time intervals and to determine the setpoint specification of the physical state.
• the predetermined course 14 may be deposited.
• a detection of the voltage of the battery 24 and taking into account the amount of charge provided to the battery 24 allows obtaining the course 12 in the ongoing Betheb (online), so that a determination of values of the reference current profile and / or a determination of values of the setpoint specification of the amount of energy to be provided in ongoing operation can take place.
• the control device 34 ' is further configured to control the controllable energy source 28 deviating from the reference value specification of the reference current profile so that the battery 24 is charged or discharged with a lower or higher level of electrical energy, if the deviation between the Soilwertvorgabe the physical state and the detected physical state is greater than, for example, 3%, greater than 5%, or greater than 10%.
• a plurality of reference current profiles can also be stored in the memory 38, in order to enable a repeated execution of the formation with a respectively adapted reference current profile.
• One aspect of embodiments described herein resides in the ability to accelerate the formation of the battery to be formed by increasing the amount of electrical energy (current) during at least one time interval from the waveforms 12 or 14 of constant current formation. While the waveforms 12 and 14 shown in FIG. 4 may have a small or negligible error between a no-load voltage and the actual voltage across the battery based on the low current level, increasing the current in some batteries may cause one to be at the battery poles voltage applied deviates during the formation of an open circuit voltage.
• the open-circuit voltage in this context is a battery voltage in a no-load State understood the same and can therefore be understood as a no-load voltage.
• the capacitor effects and / or diffusion effects may decay, the latter being optional.
• a deviation may be increasingly stronger.
• the applied voltage may be higher than the open circuit voltage or, in the case of an increasing discharge of the battery to be formed, lower than the open circuit voltage.
• no-load voltage can be understood a state of the battery in which no load or power source is connected to the poles of the battery.
• control device 32, 34 and / or 34 'of the devices described in FIGS. 6-8 is designed to carry out a correction of the reference energy profile, as described with reference to FIG represents a charging process, but is transferable without restrictions on a discharge.
• FIG. 9 shows a schematic diagram with a profile of a battery voltage during a forming process, as can be obtained according to an embodiment of exemplary embodiments described herein.
• the control device may be configured to interrupt the charging or discharging power supply to the battery at a time.
• the control device is designed to detect a physical quantity, for example the potentially faulty voltage at the battery poles U Ba tt.
• the control device may be designed to detect the physical quantity (voltage) at the time or shortly before the time.
• the voltage has, for example, a value.
• the control device detects the voltage U Ba tt short, ie at most a few seconds or minutes, before or at the time of interruption.
• other physical quantities such as quantities of charge carriers, currents or the like, can be detected via corresponding conversion quantities.
• control device is configured to control the energy supply or energy entnähme interrupted for a time interval At to hold, resulting in a variation of the voltage U B at t (from the value -. Makes ⁇ toward the value U 2 U 2 may be used as blanks running voltage, wherein a length of the interval At may affect a value of U 2 , which will be described later.
• the control device can be configured to re-detect the voltage U Ba tt having the value U 2 at a time t 2 following the time t i, so that the control device has knowledge of a value of the open-circuit voltage.
• the control device can be designed to compare the open-circuit voltage U 2 with the reference energy profile and to determine a deviation AU between the measured voltage UL, which can be used for the determination of the applied current intensity, and the actual open-circuit voltage U 2 .
• the control device may be designed to reconnect the energy source to the battery at a time t 2 , so that the discharging process or charging process is continued.
• the control device may be configured to correct the reference energy profile by the determined deviation AU. This can be done in such a way that the physical state of the battery voltage Ußatt is corrected by the deviation AU and the current to be applied is selected based on the corrected physical state (U Ba tt - AU) in the determination of the applied current intensity. As can be seen from FIG.
• the battery voltage U Ba tt may again be corrupted by the energy supply or removal, which is at least partially compensated by the correction, so that an efficiency and accuracy of the forming process is increased despite the waiting time At.
• the waiting time At can be any time interval.
• a value of a duration of the time interval is in a range between 0.1 s and 600 s.
• the duration may be selected depending on at least one physical effect in the battery to be considered. For example, by a time duration ⁇ t in a range of at least 0.1 s and at most 1 s, it is possible to take into account mainly ohmic effects in the battery. Longer periods At of more than 1 s and at most 600 s may additionally take account of capacitor effects and / or diffusion effects in the battery.
• the control device is designed to execute the correction based on an auxiliary variable, such as an internal resistance of the battery 24.
• the control device may be formed, based on the voltage values U ⁇ U 2 and on the amount of energy before the interruption to the Battery was calculated using the Ohm's laws to calculate the auxiliary size for the battery.
• the following statements relate to a calculation of the auxiliary size as the internal resistance of the battery. It should be understood, however, that any other quantity may be used that includes a combination of the voltage values U ⁇ U 2 and the amount of energy, such as a conductance or other - not physically common - mathematical quantities.
• the control device may be designed to determine the internal resistance using the determined deviation AU and / or to compare the internal resistance with a reference internal resistance.
• the determination of the internal resistance can be carried out using the ohmic law.
• the internal resistance changes with the increasing formation of the SEI on the battery.
• time intervals may exist in which the voltage across the battery changes relatively strongly during the charging or discharging process and at the same time little SEI is formed, ie. H. a small amount of added energy is converted into SEI formation and a high proportion into the charge of the battery.
• the open circuit voltage changes to a greater extent, while the internal resistance changes slightly.
• Use of the internal resistance for the purpose of correction thus allows a further increase in the precision of the process, since it provides an indication of the actual state of the battery.
• the particular internal resistance may be converted to a voltage value by which the reference energy profile is corrected taking into account the current supplied to the battery after the interruption. If the current is unchanged from a value before the interruption, the result may be AU. However, if a modified current is applied, an altered voltage difference AU 'can be obtained as a correction value.
• the determined voltage value may form an offset value by which the reference energy profile is corrected, which is also referred to as a shift of the reference energy profile by the offset value on the x-axis of a graph analogous to FIG. 4, d. H. current to be applied via voltage at the battery poles, can be understood.
• auxiliary size is now illustrated by a theoretical analysis. If, after the interruption, a higher or lower current were applied to the battery than before the interruption of the power supply, an additional error would already be present if the voltage difference AU were used purely for the correction, which is not taken into account in the previously executed correction value determination. However, if the auxiliary size is used, the new, changed current can be combined with the auxiliary quantity and a different voltage difference than previously obtained as a result. This other voltage difference can be used as a correction value or offset value and simultaneously takes into account the change in the amount of energy supplied.
• the reference internal resistance can, for example, also be detected during the first course 12 and / or second course 14 and stored for the control device.
• the control device may be designed to correct the reference energy profile based on the determined internal resistance or a comparison thereof with a reference internal resistance.
• Correction using the open circuit voltage can provide sufficient accuracy, especially as long as there is no re-adjustment of the current.
• the specific deviation between the voltages Ui and U 2 can deviate from an actual state of the battery, since a current adaptation can also lead to a change in the deviation between the actual voltage U-1 and the open-circuit voltage U 2 .
• This means that a renewed increase of the current can lead to an additional error, which is still undetermined at this time, ie the particular AU is possibly incorrect. This could be remedied by fault determination or correction at any time a power adjustment is made.
• it can be advantageous to use the internal resistance because the internal resistance is not affected or to a small extent by a current adjustment.
• the determined internal resistance can thus also be used for future adaptations, so that a number of interruptions for determining the internal resistance and hence a time loss due to the correction are small.
• the described correction can also be applied in an online method, as described in connection with FIG. 8. There, the amount of electrical energy can be determined during operation. This amount of electrical energy can then be corrected by applying the correction method so that a corrected value is already applied.
• a frequency of the measurements of the open-circuit voltage and / or the determination of the internal resistance can take place in any frequency and, for example, correspond to the frequency at which the deviations 16a-a are determined.
• a measurement of the open-circuit voltage and / or a determination of the internal resistance or it can be carried out a measurement of the open circuit voltage and / or a determination of the internal resistance independent of the time intervals.
• a method of correcting a reference energy profile may include the steps of: charging or discharging a battery to be formed having a reference energy profile that includes information about an electrical quantity to be supplied to the battery, such as a current.
• a determination of a first physical size of the battery may be made at a first time. It may be a interruption of the charging or discharging of the battery is performed and determining the first physical quantity of the battery at a second time t 2, which follows the first point in time, are carried out.
• the method may include determining a deviation between the first physical quantity at the first time and the first physical quantity at the second time, correcting the reference energy profile based on the determined deviation, a resumption of loading or unloading.
• Advantageous developments of the method may be configured such that the reference energy profile has the information about the electrical quantity to be supplied to the battery as a function of voltage applied to battery poles of the battery, that the first physical condition is the voltage applied to battery poles of the battery and in that the correction of the reference energy profile is based on the determined deviation.
• Other advantageous developments of the method may be configured such that an auxiliary quantity for the battery is based on the deviation and based on the electrical quantity delivered to the battery before the interruption with a first value (Current) is determined.
• a correction value for the reference energy profile may be determined based on the auxiliary quantity and based on a second value of the electrical quantity delivered to the battery that is applied after the resumption. This may be different or the same as the first value.
• the reference energy profile may be corrected based on the determined correction value. This correction may be performed by devices of the embodiments described herein independently or in combination with other methods.
• the advantageous embodiments may be designed such that the first physical size of the battery 24 at the second time t 2 is an open-circuit voltage U 2 of the battery 24.
• the charging or discharging accelerated with respect to the first or second waveform may result in a deviation of the voltage applied to the battery poles from the open circuit voltage of the first or second waveform, so that an inaccuracy occurs during the formation when the voltage across the battery poles with the Open circuit voltage is equated.
• This inaccuracy can be reduced by taking the actual no-load voltage and can be further reduced if the internal resistance is used as a correction parameter.
• control device in 32, 34 and / or 34 ' can also be designed such that it can determine the actual internal resistance of the connected cell and can adapt the reference current profile or reference energy profile accordingly.
• the reference current profile can be modified such that, for example, it is an amount on the x-axis (see Fig. 4) is shifted, which is calculated from the current and the measured internal resistance by applying the ohms laws, so the reference profile is corrected with respect to the effects of changing internal resistance.
• the method 900 includes a step 910 in which an electrical energy gie is supplied to a coupled to a controllable power source battery with a controllable power source.
• the controllable energy source is controlled at a plurality of time intervals.
• a physical condition of the battery is determined at each of the time intervals, and based on the determined physical condition, the electric power source is controlled to supply an amount of electric power supplied to the battery during a subsequent time interval. is increased or decreased.
• FIGS. 12a-d described below schematically illustrate the applicability of previously described exemplary embodiments for the creation of a reference energy profile and / or its application.
• the normally formed battery is referred to in the following figures as X2 and can be understood as a shaped battery or battery cell whose SEI is formed or sufficiently formed.
• X1 and X3 are respectively batteries that are not or not yet sufficiently formed, called.
• a reference profile described below can, for example, be understood as meaning that a comparison is made between two cells, for example the comparison between measured values described in connection with FIG. 4.
• a difference of measured values can be formed, which is based on a dU / dQ curve, i. a voltage change related to a received charge carrier amount, between different charging and / or discharging relates.
• a course denoted Y2 can refer to a normal profile of the normal-formed cell X2, which is compared to a curve Y1 of an unformed cell X1 or X3.
• a reference energy profile such as a current profile for the formation of the battery X3 may be calculated or obtained instead of an initial measurement by means of a simulation, which is referred to as Y3.
• FIG. 12 a shows a schematic flowchart of a method 1 100, in which a reference test with an unformed battery test cell, ie, with a battery X 1, is carried out in a step 11.
• a reference profile Y1 is derived, for example by comparing the measured values obtained in step 110 with a normal profile Y2.
• a formation of at least one battery cell X3 can take place by means of the reference profile.
• step 1 1 10 may Step 1 10 and / or step 210 include.
• Step 1 120 may include steps 120, 130, and / or 220, for example.
• Step 1 130 may include method 900.
• step 12 b shows a schematic flow diagram of a method 1 100 'modified in comparison with method 1 100.
• the method 1 100 As an alternative to the step 1 10, the method 1 100 'a step 1 1 10', which can be performed alternatively or in addition to the step 1 110.
• step 1110 ' a simulation (Y3) of an unformed or only partially formed battery cell X1 with a formed battery test cell X2 takes place.
• a corresponding simulation can therefore also be carried out instead of a test of a battery cell.
• FIG. 12 c shows a schematic flow diagram of a method 1 150, which has a step 1 152, in which an already formed battery test cell X 2 is examined. From this, in a step 1 154, a standard profile Y2 can be derived, as is known. From the standard profile obtained in step 1 154 and the measured values, a reference profile Y1 can be obtained in step 1 156, which can take place in a kind of control loop. For this purpose, for example, in a step 1 158, a start of the formation with standard values, as predetermined, for example, by the standard profile, takes place. Based on the measured values acquired during the formation, as described in connection with FIG. 7.
• a step 162 the formation obtained by the start 1 158 and the measurement of the values of the battery cell X3, alternatively X1, are shown. These measured values are compared with the standard profile Y2 in step 1 156. The standard profile Y2 is adjusted based on the comparison to obtain the reference profile Y1. This means that the forming characteristics can be adjusted during formation and during operation.
• FIG. 12 d shows a schematic flow diagram of a method 1 150 'for forming a battery.
• the method 1 150 ' has a step 1 152' that can be executed alternatively or in addition to the step 1 152 of the method 1 50.
• step 1 152 ' a simulation Y3 of a formed battery test cell X2 takes place, which means that instead of the test and / or the measurement in step 1 152, a simulation of the formed battery can take place.
• current can play a crucial role in SEI formation. The current can have different effects during different stages of formation.
• the electrochemical behavior of battery cells may depend on many factors, such as cell chemistry, geometry, or the like.
• the electrical current may be adjusted to the current property of the cell to achieve optimum process speed and product quality
• the shaping electronics can regulate the current in such a way that it corresponds to a profile (reference current profile) previously defined for the cell.
• the current can be adjusted by different measured values (physical states) of the respective cell. This allows data processing and a new calculation of the amount of energy derived therefrom for each period of time.
• the application of the reference current profile and the use of the measured values can be combined.
• Previously described embodiments can be applied to all battery cells that form an SEI on the anode and / or cathode boundary layer during the first charge and discharge processes.
• lithium-ion cells with Graphi carbon or silicon anode are listed here.
• a dynamic adjustment of the current or the amount of electrical energy can lead to the current at any time being the optimum for the cell.
• Previously described embodiments relate to a battery cell to be charged, which is electrically connected via a contact with a (direct) current source.
• the formation can be done by means of a dynamic current.
• the electric current can dynamically increase or decrease at any time of consideration.
• the amperage can be defined either by a predefined profile. This profile can be determined from the beginning by a reference measurement or a reference shaping or determined by a simulation model based on a model.
• the reference current profile may determine the current level for a given time or voltage of the battery, in addition to which the number of cycles and the direction of the current may play a role.
• the reference current profile may alternatively or additionally also refer to a discharge of the battery with a defined current intensity. In simple terms, a discharge process can be considered a reversal of the current direction be described so that the mechanisms listed above remain effective without relevant restriction.
• the current can be calculated from a signal or value measured by one or more sensors (detection means).
• detection means can be the voltage, time, current, temperature and / or quantities derived therefrom, such as the electric charge.
• a system can be implemented which is composed of both methods, such as the device 80. For example, a profile is specified, which is revised and / or modified on the basis of measured values.
• Embodiments described above allow a significant acceleration of the forming process with constant or even improved cycle stability of the battery cell.
• the shortening of the process creates a time and economic advantage.
• a high quality (quality improvement) of the formed SEI can be achieved.
• Previously described embodiments can be used in the manufacture of battery cells, in particular of lithium-ion cells, but also in other battery cells comprising other cell chemistries having an SEI formation.
• these may be cells with silicon as the anode material instead of a graphite material.
• embodiments described above can be used for forming during the production of battery cells.
• some aspects have been described in the context of a device, it will be understood that these aspects also constitute a description of the corresponding method, so that a block or a component of a device is also to be understood as a corresponding method step or as a feature of a method step.
• aspects described in connection with or as a method step also represent a description of a corresponding block or detail or feature of a corresponding device.
• embodiments of the invention may be implemented in hardware or in software.
• the implementation may be performed using a digital storage medium, such as a floppy disk, a DVD, a Blu-ray Disc, a CD, a ROM, a PROM, an EPROM, an EEPROM or FLASH memory, a hard disk, or other magnetic disk or optical memory are stored on the electronically readable control signals that can cooperate with a programmable computer system or cooperate such that the respective method is performed. Therefore, the digital storage medium can be computer readable.
• some embodiments according to the invention include a data carrier having electronically readable control signals capable of interacting with a programmable computer system such that one of the methods described herein is performed.
• embodiments of the present invention may be implemented as a computer program product having a program code, wherein the program code is operable to perform one of the methods when the computer program product runs on a computer.
• the program code can also be stored, for example, on a machine-readable carrier.
• inventions include the computer program for performing any of the methods described herein, wherein the computer program is stored on a machine-readable medium.
• an embodiment of the method according to the invention is thus a computer program which has a program code for performing one of the methods described herein when the computer program runs on a computer.
• a further embodiment of the inventive method is thus a data carrier (or a digital storage medium or a computer-readable medium) on which the computer program is recorded for carrying out one of the methods described herein.
• a further exemplary embodiment of the method according to the invention is thus a data stream or a sequence of signals which represents or represents the computer program for performing one of the methods described herein. That one- The current or the sequence of signals can be configured, for example, to be transferred via a data communication connection, for example via the Internet.
• a processing device such as a computer or a programmable logic device, that is configured or adapted to perform one of the methods described herein.
• Another embodiment includes a computer on which the computer program is installed to perform one of the methods described herein.
• a programmable logic device eg, a field programmable gate array, an FPGA
• a field programmable gate array may cooperate with a microprocessor to perform one of the methods described herein.
• the methods are performed by any hardware device. This may be a universal hardware such as a computer processor (CPU) or hardware specific to the process, such as an ASIC.
• the controllable energy source can also be controlled or designed so that the determined amount of energy is passed through current pulses or a wave current to the battery to be formed.
• the adjustment of the amount of energy, as described in the embodiments, can then be done by a variation of the frequency or the current pulse height or the amplitude size.

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